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workqueue.rs
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workqueue.rs
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// SPDX-License-Identifier: GPL-2.0
//! Work queues.
//!
//! This file has two components: The raw work item API, and the safe work item API.
//!
//! One pattern that is used in both APIs is the `ID` const generic, which exists to allow a single
//! type to define multiple `work_struct` fields. This is done by choosing an id for each field,
//! and using that id to specify which field you wish to use. (The actual value doesn't matter, as
//! long as you use different values for different fields of the same struct.) Since these IDs are
//! generic, they are used only at compile-time, so they shouldn't exist in the final binary.
//!
//! # The raw API
//!
//! The raw API consists of the [`RawWorkItem`] trait, where the work item needs to provide an
//! arbitrary function that knows how to enqueue the work item. It should usually not be used
//! directly, but if you want to, you can use it without using the pieces from the safe API.
//!
//! # The safe API
//!
//! The safe API is used via the [`Work`] struct and [`WorkItem`] traits. Furthermore, it also
//! includes a trait called [`WorkItemPointer`], which is usually not used directly by the user.
//!
//! * The [`Work`] struct is the Rust wrapper for the C `work_struct` type.
//! * The [`WorkItem`] trait is implemented for structs that can be enqueued to a workqueue.
//! * The [`WorkItemPointer`] trait is implemented for the pointer type that points at a something
//! that implements [`WorkItem`].
//!
//! ## Example
//!
//! This example defines a struct that holds an integer and can be scheduled on the workqueue. When
//! the struct is executed, it will print the integer. Since there is only one `work_struct` field,
//! we do not need to specify ids for the fields.
//!
//! ```
//! use kernel::sync::Arc;
//! use kernel::workqueue::{self, impl_has_work, new_work, Work, WorkItem};
//!
//! #[pin_data]
//! struct MyStruct {
//! value: i32,
//! #[pin]
//! work: Work<MyStruct>,
//! }
//!
//! impl_has_work! {
//! impl HasWork<Self> for MyStruct { self.work }
//! }
//!
//! impl MyStruct {
//! fn new(value: i32) -> Result<Arc<Self>> {
//! Arc::pin_init(pin_init!(MyStruct {
//! value,
//! work <- new_work!("MyStruct::work"),
//! }), GFP_KERNEL)
//! }
//! }
//!
//! impl WorkItem for MyStruct {
//! type Pointer = Arc<MyStruct>;
//!
//! fn run(this: Arc<MyStruct>) {
//! pr_info!("The value is: {}", this.value);
//! }
//! }
//!
//! /// This method will enqueue the struct for execution on the system workqueue, where its value
//! /// will be printed.
//! fn print_later(val: Arc<MyStruct>) {
//! let _ = workqueue::system().enqueue(val);
//! }
//! ```
//!
//! The following example shows how multiple `work_struct` fields can be used:
//!
//! ```
//! use kernel::sync::Arc;
//! use kernel::workqueue::{self, impl_has_work, new_work, Work, WorkItem};
//!
//! #[pin_data]
//! struct MyStruct {
//! value_1: i32,
//! value_2: i32,
//! #[pin]
//! work_1: Work<MyStruct, 1>,
//! #[pin]
//! work_2: Work<MyStruct, 2>,
//! }
//!
//! impl_has_work! {
//! impl HasWork<Self, 1> for MyStruct { self.work_1 }
//! impl HasWork<Self, 2> for MyStruct { self.work_2 }
//! }
//!
//! impl MyStruct {
//! fn new(value_1: i32, value_2: i32) -> Result<Arc<Self>> {
//! Arc::pin_init(pin_init!(MyStruct {
//! value_1,
//! value_2,
//! work_1 <- new_work!("MyStruct::work_1"),
//! work_2 <- new_work!("MyStruct::work_2"),
//! }), GFP_KERNEL)
//! }
//! }
//!
//! impl WorkItem<1> for MyStruct {
//! type Pointer = Arc<MyStruct>;
//!
//! fn run(this: Arc<MyStruct>) {
//! pr_info!("The value is: {}", this.value_1);
//! }
//! }
//!
//! impl WorkItem<2> for MyStruct {
//! type Pointer = Arc<MyStruct>;
//!
//! fn run(this: Arc<MyStruct>) {
//! pr_info!("The second value is: {}", this.value_2);
//! }
//! }
//!
//! fn print_1_later(val: Arc<MyStruct>) {
//! let _ = workqueue::system().enqueue::<Arc<MyStruct>, 1>(val);
//! }
//!
//! fn print_2_later(val: Arc<MyStruct>) {
//! let _ = workqueue::system().enqueue::<Arc<MyStruct>, 2>(val);
//! }
//! ```
//!
//! C header: [`include/linux/workqueue.h`](srctree/include/linux/workqueue.h)
use crate::alloc::{AllocError, Flags};
use crate::{prelude::*, sync::Arc, sync::LockClassKey, types::Opaque};
use core::marker::PhantomData;
/// Creates a [`Work`] initialiser with the given name and a newly-created lock class.
#[macro_export]
macro_rules! new_work {
($($name:literal)?) => {
$crate::workqueue::Work::new($crate::optional_name!($($name)?), $crate::static_lock_class!())
};
}
pub use new_work;
/// A kernel work queue.
///
/// Wraps the kernel's C `struct workqueue_struct`.
///
/// It allows work items to be queued to run on thread pools managed by the kernel. Several are
/// always available, for example, `system`, `system_highpri`, `system_long`, etc.
#[repr(transparent)]
pub struct Queue(Opaque<bindings::workqueue_struct>);
// SAFETY: Accesses to workqueues used by [`Queue`] are thread-safe.
unsafe impl Send for Queue {}
// SAFETY: Accesses to workqueues used by [`Queue`] are thread-safe.
unsafe impl Sync for Queue {}
impl Queue {
/// Use the provided `struct workqueue_struct` with Rust.
///
/// # Safety
///
/// The caller must ensure that the provided raw pointer is not dangling, that it points at a
/// valid workqueue, and that it remains valid until the end of `'a`.
pub unsafe fn from_raw<'a>(ptr: *const bindings::workqueue_struct) -> &'a Queue {
// SAFETY: The `Queue` type is `#[repr(transparent)]`, so the pointer cast is valid. The
// caller promises that the pointer is not dangling.
unsafe { &*(ptr as *const Queue) }
}
/// Enqueues a work item.
///
/// This may fail if the work item is already enqueued in a workqueue.
///
/// The work item will be submitted using `WORK_CPU_UNBOUND`.
pub fn enqueue<W, const ID: u64>(&self, w: W) -> W::EnqueueOutput
where
W: RawWorkItem<ID> + Send + 'static,
{
let queue_ptr = self.0.get();
// SAFETY: We only return `false` if the `work_struct` is already in a workqueue. The other
// `__enqueue` requirements are not relevant since `W` is `Send` and static.
//
// The call to `bindings::queue_work_on` will dereference the provided raw pointer, which
// is ok because `__enqueue` guarantees that the pointer is valid for the duration of this
// closure.
//
// Furthermore, if the C workqueue code accesses the pointer after this call to
// `__enqueue`, then the work item was successfully enqueued, and `bindings::queue_work_on`
// will have returned true. In this case, `__enqueue` promises that the raw pointer will
// stay valid until we call the function pointer in the `work_struct`, so the access is ok.
unsafe {
w.__enqueue(move |work_ptr| {
bindings::queue_work_on(
bindings::wq_misc_consts_WORK_CPU_UNBOUND as _,
queue_ptr,
work_ptr,
)
})
}
}
/// Tries to spawn the given function or closure as a work item.
///
/// This method can fail because it allocates memory to store the work item.
pub fn try_spawn<T: 'static + Send + FnOnce()>(
&self,
flags: Flags,
func: T,
) -> Result<(), AllocError> {
let init = pin_init!(ClosureWork {
work <- new_work!("Queue::try_spawn"),
func: Some(func),
});
self.enqueue(KBox::pin_init(init, flags).map_err(|_| AllocError)?);
Ok(())
}
}
/// A helper type used in [`try_spawn`].
///
/// [`try_spawn`]: Queue::try_spawn
#[pin_data]
struct ClosureWork<T> {
#[pin]
work: Work<ClosureWork<T>>,
func: Option<T>,
}
impl<T> ClosureWork<T> {
fn project(self: Pin<&mut Self>) -> &mut Option<T> {
// SAFETY: The `func` field is not structurally pinned.
unsafe { &mut self.get_unchecked_mut().func }
}
}
impl<T: FnOnce()> WorkItem for ClosureWork<T> {
type Pointer = Pin<KBox<Self>>;
fn run(mut this: Pin<KBox<Self>>) {
if let Some(func) = this.as_mut().project().take() {
(func)()
}
}
}
/// A raw work item.
///
/// This is the low-level trait that is designed for being as general as possible.
///
/// The `ID` parameter to this trait exists so that a single type can provide multiple
/// implementations of this trait. For example, if a struct has multiple `work_struct` fields, then
/// you will implement this trait once for each field, using a different id for each field. The
/// actual value of the id is not important as long as you use different ids for different fields
/// of the same struct. (Fields of different structs need not use different ids.)
///
/// Note that the id is used only to select the right method to call during compilation. It won't be
/// part of the final executable.
///
/// # Safety
///
/// Implementers must ensure that any pointers passed to a `queue_work_on` closure by [`__enqueue`]
/// remain valid for the duration specified in the guarantees section of the documentation for
/// [`__enqueue`].
///
/// [`__enqueue`]: RawWorkItem::__enqueue
pub unsafe trait RawWorkItem<const ID: u64> {
/// The return type of [`Queue::enqueue`].
type EnqueueOutput;
/// Enqueues this work item on a queue using the provided `queue_work_on` method.
///
/// # Guarantees
///
/// If this method calls the provided closure, then the raw pointer is guaranteed to point at a
/// valid `work_struct` for the duration of the call to the closure. If the closure returns
/// true, then it is further guaranteed that the pointer remains valid until someone calls the
/// function pointer stored in the `work_struct`.
///
/// # Safety
///
/// The provided closure may only return `false` if the `work_struct` is already in a workqueue.
///
/// If the work item type is annotated with any lifetimes, then you must not call the function
/// pointer after any such lifetime expires. (Never calling the function pointer is okay.)
///
/// If the work item type is not [`Send`], then the function pointer must be called on the same
/// thread as the call to `__enqueue`.
unsafe fn __enqueue<F>(self, queue_work_on: F) -> Self::EnqueueOutput
where
F: FnOnce(*mut bindings::work_struct) -> bool;
}
/// Defines the method that should be called directly when a work item is executed.
///
/// This trait is implemented by `Pin<KBox<T>>` and [`Arc<T>`], and is mainly intended to be
/// implemented for smart pointer types. For your own structs, you would implement [`WorkItem`]
/// instead. The [`run`] method on this trait will usually just perform the appropriate
/// `container_of` translation and then call into the [`run`][WorkItem::run] method from the
/// [`WorkItem`] trait.
///
/// This trait is used when the `work_struct` field is defined using the [`Work`] helper.
///
/// # Safety
///
/// Implementers must ensure that [`__enqueue`] uses a `work_struct` initialized with the [`run`]
/// method of this trait as the function pointer.
///
/// [`__enqueue`]: RawWorkItem::__enqueue
/// [`run`]: WorkItemPointer::run
pub unsafe trait WorkItemPointer<const ID: u64>: RawWorkItem<ID> {
/// Run this work item.
///
/// # Safety
///
/// The provided `work_struct` pointer must originate from a previous call to [`__enqueue`]
/// where the `queue_work_on` closure returned true, and the pointer must still be valid.
///
/// [`__enqueue`]: RawWorkItem::__enqueue
unsafe extern "C" fn run(ptr: *mut bindings::work_struct);
}
/// Defines the method that should be called when this work item is executed.
///
/// This trait is used when the `work_struct` field is defined using the [`Work`] helper.
pub trait WorkItem<const ID: u64 = 0> {
/// The pointer type that this struct is wrapped in. This will typically be `Arc<Self>` or
/// `Pin<KBox<Self>>`.
type Pointer: WorkItemPointer<ID>;
/// The method that should be called when this work item is executed.
fn run(this: Self::Pointer);
}
/// Links for a work item.
///
/// This struct contains a function pointer to the [`run`] function from the [`WorkItemPointer`]
/// trait, and defines the linked list pointers necessary to enqueue a work item in a workqueue.
///
/// Wraps the kernel's C `struct work_struct`.
///
/// This is a helper type used to associate a `work_struct` with the [`WorkItem`] that uses it.
///
/// [`run`]: WorkItemPointer::run
#[pin_data]
#[repr(transparent)]
pub struct Work<T: ?Sized, const ID: u64 = 0> {
#[pin]
work: Opaque<bindings::work_struct>,
_inner: PhantomData<T>,
}
// SAFETY: Kernel work items are usable from any thread.
//
// We do not need to constrain `T` since the work item does not actually contain a `T`.
unsafe impl<T: ?Sized, const ID: u64> Send for Work<T, ID> {}
// SAFETY: Kernel work items are usable from any thread.
//
// We do not need to constrain `T` since the work item does not actually contain a `T`.
unsafe impl<T: ?Sized, const ID: u64> Sync for Work<T, ID> {}
impl<T: ?Sized, const ID: u64> Work<T, ID> {
/// Creates a new instance of [`Work`].
#[inline]
pub fn new(name: &'static CStr, key: &'static LockClassKey) -> impl PinInit<Self>
where
T: WorkItem<ID>,
{
pin_init!(Self {
work <- Opaque::ffi_init(|slot| {
// SAFETY: The `WorkItemPointer` implementation promises that `run` can be used as
// the work item function.
unsafe {
bindings::init_work_with_key(
slot,
Some(T::Pointer::run),
false,
name.as_char_ptr(),
key.as_ptr(),
)
}
}),
_inner: PhantomData,
})
}
/// Get a pointer to the inner `work_struct`.
///
/// # Safety
///
/// The provided pointer must not be dangling and must be properly aligned. (But the memory
/// need not be initialized.)
#[inline]
pub unsafe fn raw_get(ptr: *const Self) -> *mut bindings::work_struct {
// SAFETY: The caller promises that the pointer is aligned and not dangling.
//
// A pointer cast would also be ok due to `#[repr(transparent)]`. We use `addr_of!` so that
// the compiler does not complain that the `work` field is unused.
unsafe { Opaque::raw_get(core::ptr::addr_of!((*ptr).work)) }
}
}
/// Declares that a type has a [`Work<T, ID>`] field.
///
/// The intended way of using this trait is via the [`impl_has_work!`] macro. You can use the macro
/// like this:
///
/// ```no_run
/// use kernel::workqueue::{impl_has_work, Work};
///
/// struct MyWorkItem {
/// work_field: Work<MyWorkItem, 1>,
/// }
///
/// impl_has_work! {
/// impl HasWork<MyWorkItem, 1> for MyWorkItem { self.work_field }
/// }
/// ```
///
/// Note that since the [`Work`] type is annotated with an id, you can have several `work_struct`
/// fields by using a different id for each one.
///
/// # Safety
///
/// The [`OFFSET`] constant must be the offset of a field in `Self` of type [`Work<T, ID>`]. The
/// methods on this trait must have exactly the behavior that the definitions given below have.
///
/// [`impl_has_work!`]: crate::impl_has_work
/// [`OFFSET`]: HasWork::OFFSET
pub unsafe trait HasWork<T, const ID: u64 = 0> {
/// The offset of the [`Work<T, ID>`] field.
const OFFSET: usize;
/// Returns the offset of the [`Work<T, ID>`] field.
///
/// This method exists because the [`OFFSET`] constant cannot be accessed if the type is not
/// [`Sized`].
///
/// [`OFFSET`]: HasWork::OFFSET
#[inline]
fn get_work_offset(&self) -> usize {
Self::OFFSET
}
/// Returns a pointer to the [`Work<T, ID>`] field.
///
/// # Safety
///
/// The provided pointer must point at a valid struct of type `Self`.
#[inline]
unsafe fn raw_get_work(ptr: *mut Self) -> *mut Work<T, ID> {
// SAFETY: The caller promises that the pointer is valid.
unsafe { (ptr as *mut u8).add(Self::OFFSET) as *mut Work<T, ID> }
}
/// Returns a pointer to the struct containing the [`Work<T, ID>`] field.
///
/// # Safety
///
/// The pointer must point at a [`Work<T, ID>`] field in a struct of type `Self`.
#[inline]
unsafe fn work_container_of(ptr: *mut Work<T, ID>) -> *mut Self
where
Self: Sized,
{
// SAFETY: The caller promises that the pointer points at a field of the right type in the
// right kind of struct.
unsafe { (ptr as *mut u8).sub(Self::OFFSET) as *mut Self }
}
}
/// Used to safely implement the [`HasWork<T, ID>`] trait.
///
/// # Examples
///
/// ```
/// use kernel::sync::Arc;
/// use kernel::workqueue::{self, impl_has_work, Work};
///
/// struct MyStruct<'a, T, const N: usize> {
/// work_field: Work<MyStruct<'a, T, N>, 17>,
/// f: fn(&'a [T; N]),
/// }
///
/// impl_has_work! {
/// impl{'a, T, const N: usize} HasWork<MyStruct<'a, T, N>, 17>
/// for MyStruct<'a, T, N> { self.work_field }
/// }
/// ```
#[macro_export]
macro_rules! impl_has_work {
($(impl$({$($generics:tt)*})?
HasWork<$work_type:ty $(, $id:tt)?>
for $self:ty
{ self.$field:ident }
)*) => {$(
// SAFETY: The implementation of `raw_get_work` only compiles if the field has the right
// type.
unsafe impl$(<$($generics)+>)? $crate::workqueue::HasWork<$work_type $(, $id)?> for $self {
const OFFSET: usize = ::core::mem::offset_of!(Self, $field) as usize;
#[inline]
unsafe fn raw_get_work(ptr: *mut Self) -> *mut $crate::workqueue::Work<$work_type $(, $id)?> {
// SAFETY: The caller promises that the pointer is not dangling.
unsafe {
::core::ptr::addr_of_mut!((*ptr).$field)
}
}
}
)*};
}
pub use impl_has_work;
impl_has_work! {
impl{T} HasWork<Self> for ClosureWork<T> { self.work }
}
// SAFETY: TODO.
unsafe impl<T, const ID: u64> WorkItemPointer<ID> for Arc<T>
where
T: WorkItem<ID, Pointer = Self>,
T: HasWork<T, ID>,
{
unsafe extern "C" fn run(ptr: *mut bindings::work_struct) {
// The `__enqueue` method always uses a `work_struct` stored in a `Work<T, ID>`.
let ptr = ptr as *mut Work<T, ID>;
// SAFETY: This computes the pointer that `__enqueue` got from `Arc::into_raw`.
let ptr = unsafe { T::work_container_of(ptr) };
// SAFETY: This pointer comes from `Arc::into_raw` and we've been given back ownership.
let arc = unsafe { Arc::from_raw(ptr) };
T::run(arc)
}
}
// SAFETY: TODO.
unsafe impl<T, const ID: u64> RawWorkItem<ID> for Arc<T>
where
T: WorkItem<ID, Pointer = Self>,
T: HasWork<T, ID>,
{
type EnqueueOutput = Result<(), Self>;
unsafe fn __enqueue<F>(self, queue_work_on: F) -> Self::EnqueueOutput
where
F: FnOnce(*mut bindings::work_struct) -> bool,
{
// Casting between const and mut is not a problem as long as the pointer is a raw pointer.
let ptr = Arc::into_raw(self).cast_mut();
// SAFETY: Pointers into an `Arc` point at a valid value.
let work_ptr = unsafe { T::raw_get_work(ptr) };
// SAFETY: `raw_get_work` returns a pointer to a valid value.
let work_ptr = unsafe { Work::raw_get(work_ptr) };
if queue_work_on(work_ptr) {
Ok(())
} else {
// SAFETY: The work queue has not taken ownership of the pointer.
Err(unsafe { Arc::from_raw(ptr) })
}
}
}
// SAFETY: TODO.
unsafe impl<T, const ID: u64> WorkItemPointer<ID> for Pin<KBox<T>>
where
T: WorkItem<ID, Pointer = Self>,
T: HasWork<T, ID>,
{
unsafe extern "C" fn run(ptr: *mut bindings::work_struct) {
// The `__enqueue` method always uses a `work_struct` stored in a `Work<T, ID>`.
let ptr = ptr as *mut Work<T, ID>;
// SAFETY: This computes the pointer that `__enqueue` got from `Arc::into_raw`.
let ptr = unsafe { T::work_container_of(ptr) };
// SAFETY: This pointer comes from `Arc::into_raw` and we've been given back ownership.
let boxed = unsafe { KBox::from_raw(ptr) };
// SAFETY: The box was already pinned when it was enqueued.
let pinned = unsafe { Pin::new_unchecked(boxed) };
T::run(pinned)
}
}
// SAFETY: TODO.
unsafe impl<T, const ID: u64> RawWorkItem<ID> for Pin<KBox<T>>
where
T: WorkItem<ID, Pointer = Self>,
T: HasWork<T, ID>,
{
type EnqueueOutput = ();
unsafe fn __enqueue<F>(self, queue_work_on: F) -> Self::EnqueueOutput
where
F: FnOnce(*mut bindings::work_struct) -> bool,
{
// SAFETY: We're not going to move `self` or any of its fields, so its okay to temporarily
// remove the `Pin` wrapper.
let boxed = unsafe { Pin::into_inner_unchecked(self) };
let ptr = KBox::into_raw(boxed);
// SAFETY: Pointers into a `KBox` point at a valid value.
let work_ptr = unsafe { T::raw_get_work(ptr) };
// SAFETY: `raw_get_work` returns a pointer to a valid value.
let work_ptr = unsafe { Work::raw_get(work_ptr) };
if !queue_work_on(work_ptr) {
// SAFETY: This method requires exclusive ownership of the box, so it cannot be in a
// workqueue.
unsafe { ::core::hint::unreachable_unchecked() }
}
}
}
/// Returns the system work queue (`system_wq`).
///
/// It is the one used by `schedule[_delayed]_work[_on]()`. Multi-CPU multi-threaded. There are
/// users which expect relatively short queue flush time.
///
/// Callers shouldn't queue work items which can run for too long.
pub fn system() -> &'static Queue {
// SAFETY: `system_wq` is a C global, always available.
unsafe { Queue::from_raw(bindings::system_wq) }
}
/// Returns the system high-priority work queue (`system_highpri_wq`).
///
/// It is similar to the one returned by [`system`] but for work items which require higher
/// scheduling priority.
pub fn system_highpri() -> &'static Queue {
// SAFETY: `system_highpri_wq` is a C global, always available.
unsafe { Queue::from_raw(bindings::system_highpri_wq) }
}
/// Returns the system work queue for potentially long-running work items (`system_long_wq`).
///
/// It is similar to the one returned by [`system`] but may host long running work items. Queue
/// flushing might take relatively long.
pub fn system_long() -> &'static Queue {
// SAFETY: `system_long_wq` is a C global, always available.
unsafe { Queue::from_raw(bindings::system_long_wq) }
}
/// Returns the system unbound work queue (`system_unbound_wq`).
///
/// Workers are not bound to any specific CPU, not concurrency managed, and all queued work items
/// are executed immediately as long as `max_active` limit is not reached and resources are
/// available.
pub fn system_unbound() -> &'static Queue {
// SAFETY: `system_unbound_wq` is a C global, always available.
unsafe { Queue::from_raw(bindings::system_unbound_wq) }
}
/// Returns the system freezable work queue (`system_freezable_wq`).
///
/// It is equivalent to the one returned by [`system`] except that it's freezable.
///
/// A freezable workqueue participates in the freeze phase of the system suspend operations. Work
/// items on the workqueue are drained and no new work item starts execution until thawed.
pub fn system_freezable() -> &'static Queue {
// SAFETY: `system_freezable_wq` is a C global, always available.
unsafe { Queue::from_raw(bindings::system_freezable_wq) }
}
/// Returns the system power-efficient work queue (`system_power_efficient_wq`).
///
/// It is inclined towards saving power and is converted to "unbound" variants if the
/// `workqueue.power_efficient` kernel parameter is specified; otherwise, it is similar to the one
/// returned by [`system`].
pub fn system_power_efficient() -> &'static Queue {
// SAFETY: `system_power_efficient_wq` is a C global, always available.
unsafe { Queue::from_raw(bindings::system_power_efficient_wq) }
}
/// Returns the system freezable power-efficient work queue (`system_freezable_power_efficient_wq`).
///
/// It is similar to the one returned by [`system_power_efficient`] except that is freezable.
///
/// A freezable workqueue participates in the freeze phase of the system suspend operations. Work
/// items on the workqueue are drained and no new work item starts execution until thawed.
pub fn system_freezable_power_efficient() -> &'static Queue {
// SAFETY: `system_freezable_power_efficient_wq` is a C global, always available.
unsafe { Queue::from_raw(bindings::system_freezable_power_efficient_wq) }
}